BEGINNING TO CRACK THE CODE OF 'JUNK DNA'
By Faye Flam
Philadelphia Inquirer
http://www.philly.com/inquirer/front_page /20081218_Beginning_to_crack_the_code_of__junk_DNA _.html
Dec 18 2008
PA
To scientists, it was a mystery. Most of the genetic material we
carry in our cells seemed to have no purpose.
It seemed so useless, some called it "junk DNA."
Weirder still, geneticists noticed that some of the junk has a life
of its own, copying itself, viruslike, and jumping around the DNA.
This phenomenon had never been documented in humans until geneticist
Haig Kazazian started studying boys with the blood-clotting disorder
hemophilia.
Over years of painstaking research, Kazazian, now at the University
of Pennsylvania, found that these straying bits of DNA can land in
important genes like so much molecular debris - leading to a few cases
of hemophilia, muscular dystrophy, and several other genetic disorders.
For his lifetime of achievements, he was given one of the highest
honors in his field last month: the Allen Award from the American
Society of Human Genetics.
Kazazian, 71, has no plans to slow down. He is investigating whether
this type of self-replicating junk DNA holds more power over human
illness than has previously been imagined. It might influence our risk
for cancer, neurodegenerative diseases, and other common conditions.
"The one thing that drew me to Haig is his intellectual curiosity
and his fearlessness," said geneticist John Moran, who studied under
Kazazian at Johns Hopkins University before becoming a professor at
the University of Michigan. "He took the field in a new direction -
he really was one of the pioneers."
Johns Hopkins genetics professor Aravinda Chakravarti said that while
geneticists looked at mice or fruit flies in search of clues to human
disease, Kazazian also worked the other way, starting by unraveling
mysterious medical cases to better understand how human DNA works.
Oddly, humans appear to carry much more DNA than we need. If you
stretched out the DNA in just one cell, it would extend six feet -
spelling out a four-letter code three billion letters long.
In a vast sea Only 1 or 2 percent of all that is made up of genes -
sequences that spell out recipes for a host of biological molecules
known as proteins.
These genes are embedded in all of this other DNA like islands in a
vast sea.
About a third of the other 98 percent of our DNA is made of "introns"
- stretches of code that are spliced out when it's time to transcribe
the genes into proteins. The rest is the stuff formerly called junk.
If there are messages written there, they are not altogether
accessible. If the coherent 2 percent read like Harry Potter,
the so-called junk DNA could be the more opaque stretches of James
Joyce's Ulysses.
Kazazian didn't set out initially to investigate any of this. When
launching his genetics career in the 1960s, he wanted to work on
combating inherited diseases, such as hemophilia, muscular dystrophy
and thalassemia, a form of anemia.
In high school and college, he imagined that he would become a
doctor. That was the profession his father said he would have followed
had his family not been imprisoned in a Turkish concentration camp
in 1915 - along with thousands of other Armenians living in Turkey.
New vistas Kazazian's father was 14 at the time. Both of his parents,
all of his siblings, and his grandmother died in Turkey. In the early
1920s, he came to the United States and became a rug merchant. Medicine
would have to wait until the next generation.
But Kazazian switched from medicine to genetics in the 1960s, inspired
by the new vistas of knowledge the field was opening up.
In 1969, he joined the faculty at Johns Hopkins, where he began
studying genetic diseases. He and other geneticists at the time were
finding that dozens of different errors in the same gene could lead
to the same disease.
He expected something similar when he started studying hemophilia,
which is caused by various defects in a gene called factor VIII,
carried on the X chromosome.
People with hemophilia often suffer bleeding into their joints,
Kazazian said. And even a simple dental visit can leave them with
profuse bleeding. Doctors eventually learned to treat the disease by
giving patients factor VIII from donated blood.
But in the 1980s, HIV invaded the blood supply, and soon AIDS began
to tear through the hemophiliac population.
Kazazian had come across three genetically unusual cases - boys with
hemophilia whose factor VIII gene was disabled by an invading piece
of stray DNA.
The invading DNA belonged to a specific category of the junk DNA
called a transposable element. These had been observed in plants,
where they had the power to act like a virus, copying themselves and
jumping to new parts of the genetic code.
Most human transposable elements belong to a family called line1
elements. In total, Kazazian said, we carry about 500,000 of them,
making up a whopping 17 percent of human DNA, a major portion of the
so-called junk. Most of these are inert, having lost their ability
to cut and paste themselves to new locations.
But a few are still capable of jumping around and causing trouble.
How had these line1 elements gotten into the boys' factor VIII genes?
To figure it out, Kazazian was able to identify some unique stretches
of code in the line1 sequence affecting one of the boys.
Using what is called a genetic probe, he was able to find the same
sequence in a line1 element in the boy's mother, but it was in a
different place, on Chromosome 22. (Human chromosomes are all assigned
a number except the sex chromosomes, which are labeled X and Y.)
In her case, it caused no problem. Kazazian said he suspected that the
line1 element jumped from her Chromosome 22 to the X chromosome either
in the mother's egg cell or during an early stage in the development
of the embryo that became the boy.
The boy was 10 years old when Kazazian made the discovery. His case
was tragic, Kazazian said. During his teens he showed promise as an
actor, snagging a major role in the movie Lost in Yonkers. But as a
teenager, he acquired HIV from his treatment and died at 21.
Kazazian traced another hemophilia case to a jumping line1 element
and went on to find line1 elements lurking behind a case of muscular
dystrophy.
In 1994, he came to the University of Pennsylvania to head the genetics
department. He stepped down as director in 2006 but still retains an
active research agenda, supervising a coterie of scientists working
on line1 elements in animals and humans.
He is intrigued now by the possibility that active line1 elements may
copy themselves and invade DNA during human development, introducing
genetic variation within the same person's DNA.
He said there were some tantalizing hints that in brain cells, this
process could spawn variations in personality and temperament. In
other parts of the body, it could leave some cells more vulnerable
than others to cancer.
Kazazian said he was sure that his life had been channeled in part
by his father's ordeal in Turkey. "I always knew he had wanted to
become a doctor," he said. "I think he would have preferred that I
go into medical practice . . . but eventually he realized I had to
do my own thing."
By Faye Flam
Philadelphia Inquirer
http://www.philly.com/inquirer/front_page /20081218_Beginning_to_crack_the_code_of__junk_DNA _.html
Dec 18 2008
PA
To scientists, it was a mystery. Most of the genetic material we
carry in our cells seemed to have no purpose.
It seemed so useless, some called it "junk DNA."
Weirder still, geneticists noticed that some of the junk has a life
of its own, copying itself, viruslike, and jumping around the DNA.
This phenomenon had never been documented in humans until geneticist
Haig Kazazian started studying boys with the blood-clotting disorder
hemophilia.
Over years of painstaking research, Kazazian, now at the University
of Pennsylvania, found that these straying bits of DNA can land in
important genes like so much molecular debris - leading to a few cases
of hemophilia, muscular dystrophy, and several other genetic disorders.
For his lifetime of achievements, he was given one of the highest
honors in his field last month: the Allen Award from the American
Society of Human Genetics.
Kazazian, 71, has no plans to slow down. He is investigating whether
this type of self-replicating junk DNA holds more power over human
illness than has previously been imagined. It might influence our risk
for cancer, neurodegenerative diseases, and other common conditions.
"The one thing that drew me to Haig is his intellectual curiosity
and his fearlessness," said geneticist John Moran, who studied under
Kazazian at Johns Hopkins University before becoming a professor at
the University of Michigan. "He took the field in a new direction -
he really was one of the pioneers."
Johns Hopkins genetics professor Aravinda Chakravarti said that while
geneticists looked at mice or fruit flies in search of clues to human
disease, Kazazian also worked the other way, starting by unraveling
mysterious medical cases to better understand how human DNA works.
Oddly, humans appear to carry much more DNA than we need. If you
stretched out the DNA in just one cell, it would extend six feet -
spelling out a four-letter code three billion letters long.
In a vast sea Only 1 or 2 percent of all that is made up of genes -
sequences that spell out recipes for a host of biological molecules
known as proteins.
These genes are embedded in all of this other DNA like islands in a
vast sea.
About a third of the other 98 percent of our DNA is made of "introns"
- stretches of code that are spliced out when it's time to transcribe
the genes into proteins. The rest is the stuff formerly called junk.
If there are messages written there, they are not altogether
accessible. If the coherent 2 percent read like Harry Potter,
the so-called junk DNA could be the more opaque stretches of James
Joyce's Ulysses.
Kazazian didn't set out initially to investigate any of this. When
launching his genetics career in the 1960s, he wanted to work on
combating inherited diseases, such as hemophilia, muscular dystrophy
and thalassemia, a form of anemia.
In high school and college, he imagined that he would become a
doctor. That was the profession his father said he would have followed
had his family not been imprisoned in a Turkish concentration camp
in 1915 - along with thousands of other Armenians living in Turkey.
New vistas Kazazian's father was 14 at the time. Both of his parents,
all of his siblings, and his grandmother died in Turkey. In the early
1920s, he came to the United States and became a rug merchant. Medicine
would have to wait until the next generation.
But Kazazian switched from medicine to genetics in the 1960s, inspired
by the new vistas of knowledge the field was opening up.
In 1969, he joined the faculty at Johns Hopkins, where he began
studying genetic diseases. He and other geneticists at the time were
finding that dozens of different errors in the same gene could lead
to the same disease.
He expected something similar when he started studying hemophilia,
which is caused by various defects in a gene called factor VIII,
carried on the X chromosome.
People with hemophilia often suffer bleeding into their joints,
Kazazian said. And even a simple dental visit can leave them with
profuse bleeding. Doctors eventually learned to treat the disease by
giving patients factor VIII from donated blood.
But in the 1980s, HIV invaded the blood supply, and soon AIDS began
to tear through the hemophiliac population.
Kazazian had come across three genetically unusual cases - boys with
hemophilia whose factor VIII gene was disabled by an invading piece
of stray DNA.
The invading DNA belonged to a specific category of the junk DNA
called a transposable element. These had been observed in plants,
where they had the power to act like a virus, copying themselves and
jumping to new parts of the genetic code.
Most human transposable elements belong to a family called line1
elements. In total, Kazazian said, we carry about 500,000 of them,
making up a whopping 17 percent of human DNA, a major portion of the
so-called junk. Most of these are inert, having lost their ability
to cut and paste themselves to new locations.
But a few are still capable of jumping around and causing trouble.
How had these line1 elements gotten into the boys' factor VIII genes?
To figure it out, Kazazian was able to identify some unique stretches
of code in the line1 sequence affecting one of the boys.
Using what is called a genetic probe, he was able to find the same
sequence in a line1 element in the boy's mother, but it was in a
different place, on Chromosome 22. (Human chromosomes are all assigned
a number except the sex chromosomes, which are labeled X and Y.)
In her case, it caused no problem. Kazazian said he suspected that the
line1 element jumped from her Chromosome 22 to the X chromosome either
in the mother's egg cell or during an early stage in the development
of the embryo that became the boy.
The boy was 10 years old when Kazazian made the discovery. His case
was tragic, Kazazian said. During his teens he showed promise as an
actor, snagging a major role in the movie Lost in Yonkers. But as a
teenager, he acquired HIV from his treatment and died at 21.
Kazazian traced another hemophilia case to a jumping line1 element
and went on to find line1 elements lurking behind a case of muscular
dystrophy.
In 1994, he came to the University of Pennsylvania to head the genetics
department. He stepped down as director in 2006 but still retains an
active research agenda, supervising a coterie of scientists working
on line1 elements in animals and humans.
He is intrigued now by the possibility that active line1 elements may
copy themselves and invade DNA during human development, introducing
genetic variation within the same person's DNA.
He said there were some tantalizing hints that in brain cells, this
process could spawn variations in personality and temperament. In
other parts of the body, it could leave some cells more vulnerable
than others to cancer.
Kazazian said he was sure that his life had been channeled in part
by his father's ordeal in Turkey. "I always knew he had wanted to
become a doctor," he said. "I think he would have preferred that I
go into medical practice . . . but eventually he realized I had to
do my own thing."